Solution of the k-th eigenvalue problem in large-scale electronic structure calculations

Solution of the k-th eigenvalue problem in large-scale electronic structure calculations

We consider computing the k-th eigenvalue and its corresponding eigenvector of a generalized Hermitian eigenvalue problem of n×n large sparse matrices. In electronic structure calculations, several properties of materials, such as those of optoelectronic device materials, are governed by the eigenpa...

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Bibliographic Details
Published in:Journal of computational physics Vol. 371; pp. 618 - 632
Main Authors: Lee, Dongjin, Hoshi, Takeo, Sogabe, Tomohiro, Miyatake, Yuto, Zhang, Shao-Liang
Format: Journal Article
Language:English
Published: Cambridge Elsevier Inc 15-10-2018
Elsevier Science Ltd
Subjects:
Algorithms
Banach spaces
Computation
Computational physics
Eigenvalues
Eigenvectors
Electronic structure
Electronic structure calculations
Generalized eigenvalue problem
Lanczos method
Material properties
Mathematical analysis
Numerical analysis
Optoelectronic devices
Sparse direct linear solver
Sparse matrices
Sparsity
Spectral bisection
Vector space
Generalized eigenvalue problem
Spectral bisection
Sparse direct linear solver
Lanczos method
Electronic structure calculations
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Summary:We consider computing the k-th eigenvalue and its corresponding eigenvector of a generalized Hermitian eigenvalue problem of n×n large sparse matrices. In electronic structure calculations, several properties of materials, such as those of optoelectronic device materials, are governed by the eigenpair with a material-specific index k. We present a three-stage algorithm for computing the k-th eigenpair with validation of its index. In the first stage of the algorithm, we propose an efficient way of finding an interval containing the k-th eigenvalue (1≪k≪n) with a non-standard application of the Lanczos method. In the second stage, spectral bisection for large-scale problems is realized using a sparse direct linear solver to narrow down the interval of the k-th eigenvalue. In the third stage, we switch to a modified shift-and-invert Lanczos method to reduce bisection iterations and compute the k-th eigenpair with validation. Numerical results with problem sizes up to 1.5 million are reported, and the results demonstrate the accuracy and efficiency of the three-stage algorithm.
ISSN:0021-9991
1090-2716
DOI:10.1016/j.jcp.2018.06.002